Many problems in applied mathematics can be formulated as a Sylvester matrix equation AX+XB=C. Iterative methods for solving this equation are appropriate in applications coming from numerical treatment of elliptic problems and from control and systems theory. We determine the solution of this matrix equation with the Arithmetic Mean method, which is ideally suited for implementation on parallel computers. We consider different cases: A is large and sparse with a non random sparsity pattern and B is large with a simple structure; A and B are banded; A and B are large and without any special structure. The main purpose of this paper is to develop a convergence analysis of the method, using different splittings of the matrices A and B
AbstractIn this paper we show how to improve the approximate solution of the large Sylvester equatio...
This paper proposes the modified generalization of the HSS (MGHSS) to solve a large and sparse conti...
AbstractFor given matrices A∈Fm×m, B∈Fn×n, and C∈Fm×n over an arbitrary field F, the matrix equation...
Many problems in applied mathematics can be formulated as a Sylvester matrix equation AX+XB=C. Itera...
This paper is concerned with a parallel solution of the Sylvester matrix equation AX+XB=C by means o...
We present and analyze a new iterative scheme for large-scale solution of the well-known Sylvester e...
In this paper we consider the arithmetic mean method for solving large sparse systems of linear equa...
We discuss convergence properties of the GMRES and FOM methods for solving large Sylvester equations...
AbstractIn this paper we consider thearithmetic mean method for solving large sparse systems of line...
In this paper we consider thearithmetic mean method for solving large sparse systems of linear equat...
We investigate the numerical solution of stable Sylvester equations via iterative schemes proposed f...
In several recent works, the Arithmetic Mean Method for solving large sparse linear systems has been...
In this paper we propose a parallel two-stage iteration algorithm for solving large-scale continuous...
Computational effort of solving large-scale Sylvester equations AX+XB+F=O is frequently hindered in ...
We present a circulant and skew-circulant splitting (CSCS) iterative method for solving large sparse...
AbstractIn this paper we show how to improve the approximate solution of the large Sylvester equatio...
This paper proposes the modified generalization of the HSS (MGHSS) to solve a large and sparse conti...
AbstractFor given matrices A∈Fm×m, B∈Fn×n, and C∈Fm×n over an arbitrary field F, the matrix equation...
Many problems in applied mathematics can be formulated as a Sylvester matrix equation AX+XB=C. Itera...
This paper is concerned with a parallel solution of the Sylvester matrix equation AX+XB=C by means o...
We present and analyze a new iterative scheme for large-scale solution of the well-known Sylvester e...
In this paper we consider the arithmetic mean method for solving large sparse systems of linear equa...
We discuss convergence properties of the GMRES and FOM methods for solving large Sylvester equations...
AbstractIn this paper we consider thearithmetic mean method for solving large sparse systems of line...
In this paper we consider thearithmetic mean method for solving large sparse systems of linear equat...
We investigate the numerical solution of stable Sylvester equations via iterative schemes proposed f...
In several recent works, the Arithmetic Mean Method for solving large sparse linear systems has been...
In this paper we propose a parallel two-stage iteration algorithm for solving large-scale continuous...
Computational effort of solving large-scale Sylvester equations AX+XB+F=O is frequently hindered in ...
We present a circulant and skew-circulant splitting (CSCS) iterative method for solving large sparse...
AbstractIn this paper we show how to improve the approximate solution of the large Sylvester equatio...
This paper proposes the modified generalization of the HSS (MGHSS) to solve a large and sparse conti...
AbstractFor given matrices A∈Fm×m, B∈Fn×n, and C∈Fm×n over an arbitrary field F, the matrix equation...